aryl)phosphino]ferrocenes ... - American Chemical Society

Ian R. Butler, William R. Cullen,' TaeJeong Kim, Steven J. Rettig, and James Trotter. Chemistry Department, University of British Columbia, Vancouver,...
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Organometallics 1985, 4, 972-980

972

1,l'-Bis[ (alkyl/aryl)phosphino]ferrocenes: Synthesis an6 Metal Complex Formation. Crystal Structure of Three Metal Complexes of Fe( q5-C,H,PPh2), Ian R. Butler, William R. Cullen,' TaeJeong Kim, Steven J. Rettig, and James Trotter Chemistry Department, University of British Columbia, Vancouver, British Columbia, Canada, V6T 1Y6 Received August 3 1, 1984

The ferrocenylphosphines Fe(05-C6H4PR1R2)(a5-C5H4PR3R4) (R1-R4 = Ph or CMeJ are prepared by The latter reagent is obtained reacting ClPR1R2with either F e ( ~ ~ - c & L ior) ~F~(T~-C~H~L~)(V~-C~H~PR~R~). by cleavin the ferrocenophane Fe(q5-C5H4PR3)(y5-C5H4) with R4Li. Best results are obtained when either or both R and R4 are Ph. A representative range of Pd(L-L)ClZ,[Rh(L-L)NBD]ClO,, and Ni(L-L)X2 complexes has been prepared. Crystal data for the known compounds (R1--R4= Ph) (L-L)PdC12CH2C12, (L-L)NiBr2,and (L-L)MO(CO)~.C~H~ are as follows: Pd, P2,/c, a = 9.8615 8, b = 18.2322 A, c = 19.1540 A, p = 102.581°, 2 = 4; Ni, PnSla, a = 20.4163 A, b = 14.7573A, c = 10.2015 2 = 4; Mo, pi, a = 10.950 A, b = 18,110 A, c = 10.3433 A, a = 101.777", p = 93.322', y = 83.059', 2 = 2; Mo radiation; R = 0.029, 0.069, and 0.033 for 4324, 1870, and 6687 reflections, respectively. The Pd, Ni, and Mo atoms have cis square-planar, tetrahedral, and cis octahedral coordinations, respectively;mean Pd-P = 2.284 (6) A, Pd-Cl = 2.349 (9) A, Ni-P = 2.290 (9) A, Ni-Br = 2.348 (4) A, Mo-P = 2.560 (16) A, and Mo-C = 1.974 (5) (trans to P) and 2.038 (3) 8, (cis to P). The ferrocene ligands have slightly nonparallel cyclopentadienyl rings, with approximately staggered arrangements in the Pd and Mo compounds but an approximately eclipsed conformation in the Ni complex and with significant displacements of the P atoms from the ring planes. Both the molybdenum compound and its chromium analogue are fluxional in solution to -80 OC.

Q

.

A,

Introduction Ferrocenylphosphines have found useful synthetic application as ligands in the rhodium-, ruthenium-, and palladium-catalyzed hydrogenation of olefins'-' and the nickel- and palladium-catalyzed Grignard cross-coupling reactions.g11 In particular it has been found that cationic rhodium(1) complexes of 1,l'-bis(diphenylphosphin0)ferrocene, 1, are efficient hydrogenation catalysts for olefin r e d ~ c t i o n .Similarly ~ (di-tert-buty1phosphino)ferrocene derivatives such as 2 may also be employed as ligands in such reactions; use of optically pure ligand results in unexpectedly high optical yields of product from the reduction of a-(acy1amino)acrylic We are interested in the modification of chelating ferrocenylphosphine ligands, particularly 1 to establish the effect of bulky phosphorus substituents on the rate and mechanism of reaction. As part of ongoing studies the preparation of 1,l'-bis(di-tert-butylphosphino)ferrocene, 3, and a cationic rhodium(1) complex of 3 were recently d e ~ c r i b e d . We ~ now report the synthesis of a series of related 1,l'-bis[ (alkyl/aryl)phosphino] ferrocenes designed specifically for use as ligands in hydrogenation and (1)(a) Cullen, W. R.; Woollins, J. D. Coord. Chem. Reu. 1982,39,1. (b) Hayashi, T.; Kumada, M. Acc. Chem. Res. 1982,15,395.(c) Hayashi, T.; Mise, T.; Fukushima, M.; Kagotani, M.; Nagashima, N.; Hamada, Y.; Matsomoto, A.; Kawakami, S.; Konishi, M.; Yamamoto, K.; Kumada, M. Bull. Chem. SOC. Jpn. 1980,53,1138. (2)Yamamoto, K.;Watatsuki, J.; Sugimoto, R. Bull. Chem. SOC.J p n . 1980,53,1132. (3)Cullen, W. R.; Woollins, J. D. Can. J. Chem. 1982,60,1793. (4)Cullen, W. R.;Einstein, F. W. B.; Jones, T.; Kim, T.-J. Organometallics 1983,2, 714. (5)Cullen, W. R.; Kim, T.-J.; Einstein, F. W. B.; Jones, T. Organometallics 1985,4,346. (6)(a) Rodgers, G.E.; Cullen, W. R.; James, B. R. Can. J.Chem. 1983, 61, 1314. (b) Cullen, W. R.; Han, N.-F., unpublished results. (7)Cullen, W. R.; Appleton, T. D.; Evans, S. V.; Kim, T. J.; Trotter, J. T. J . Organomet. Chem. 1985,279, 5. (8)Kumada, M. Pure Appl. Chem. 1980,52,669. (9)Hayashi, T.; Konishi, M.; Fukushima, M.; Mise, T.; Kagotani, M.; Tajika, M.; Kumada, M. J. Am. Chem. SOC. 1982,104, 189. (10)Hayashi, T.; Konishi, M.; Ito, H.; Kumada, M. J . Am. Chem. SOC. 1982,104,4962. (11)Hayashi, T.; Konishi, M.; Kobori, Y.; Kumada, M.; Higuchi, T.; Hirotsu, K. J . A m . C h e n . SOC.1984,106,158.

2

1

*P(CMe3)2 Fe

-P(

CMe3 ) 2 3

cross-coupling reaction studies. In earlier studies a series of metal complexes of ligands like 1 has been prepared by the groups of Davison,12Kumada,13 and others,14 but little X-ray structural data are a ~ a i l a b l e . ~ J ~ Thus, J~ it is not known if the cyclopentadienyl rings are always eclipsed (or staggered) as in 4 (or 5) or if structural differences can account for the large differences observed in regioselectivity in cross-coupling reactions catalyzed by M(L-L)C12 (L-L = 1 and M = Ni or Pd).lb To this end we have carried out some studies of the metal complexes of the series of ligands 1, 3, and 6-9 and in this paper describe the crystal structures of Pd(L-L)C12.CH2C12,Ni(L-L)Br2,and MO(L-L)(CO)~.C~H, (L-L = 1).16

Experimental Section All experimental manipulations were carried out under an Nz or Ar atmosphere using conventional Schlenk tube techniques. (12)(a) Davison, A.; Bishop, J. J. Inorg. Chem. 1971,10,826. (b) Davison, A.; Bishop, J. J. Ibid. 1971,IO, 832. (c) Rudie, A. W.; Lichtenberg, D. W.; Katcher, M. L.; Davison, A. Inorg. Chem. 1978,17,2859.(d) Bishop, J. J.; Davison, A.; Katcher, M. L.; Lientenberg, D. W.; Merrill, R. E.; Smart, J. C. J . Organomet. Chem. 1971,27, 241. (13)(a) Hayashi, T.;Mise, T.; Kumada, M. Tetrahedron. Lett. 1976, 4351. (b) Hayashi, T.; Mise, T.; Kumada, M. Ibid. 1979,425. (c) Hayashi, T.; Konishi, M.; Kumada, M. J. Organomet. Chem. 1980,186, C1. (d) Hayashi, T.; Tamoao, K.; Katsuro, Y.; Nakae, I.; Kumada, M. Tetrahedron. Lett. 1980,1871. (14)Mague, J. T.;Nutt, M. 0. Inorg. Chem. 1977,16, 1259. (15)Pierport, C.G.;Aisenberg, R. Inorg. Chem. 1972,I I, 828. (16)The crystal structure of Pd(L-L)Cl2CHC1, (L-L = 1) was reported" during the preparation of this manuscript. We describe the structure of the closely related molecule Pd(L-L)Cl2.CH,Cl2.

0276-7333/85/2304-0972$01.50/0 0 1985 American Chemical Society

Organometallics, Vol. 4 , No. 6, 1985 973

1,l'-Bis[(alkyl/aryl)phosphino]ferrocenes

4a 4b

R2

5b

Microanalyses were performed by Mr. Peter Borda of this department. 'H and 31PNMR spectra were recorded in CDC13 solutions, except where otherwise stated, using a Bruker WP-80, a Varian XL-100, or a Bruker WH-400 spectrometer. Chemical shifts are reported in parts per million downfield from external Me4& and shifts relative to 85% H3PO4,with P(OMe)3(6 +141.0) used as external reference. Couplings are given in hertz. All solvents were predried by using conventional techniques and were freshly distilled prior to use. n-Butyllithium in hexane, tert-butyllithium in hexane, and phenyllithium in benzene were supplied by the Aldrich Chemical Co. Mass spectra were obtained by using a Kratos MS-50 spectrometer. Petroleum ether refers to the fraction bp 30-60 "C. Preparation of the Symmetrically 1,l'-Disubstituted Phosphinoferroeenes 1,3, and 6. Compounds 1 and 3 were prepared according to the literature procedures.' Compound 6 was prepared as described for the preparation of 3 replacing di-tert-butylchlorophosphinewith tert-butylchlorophenylphosphine. 6 was isolated after chromatography as a deep red oil which solidified slowly on standing at 0 OC (60% yield). The meso and racemic isomers were separated by chromatography on alumina (neutral, Grade 1)eluting with petroleum ether/diethyl ether (70/30): mp 56-58 "C (racemic); 'H NMR (CDCl,) 6 1.20 (d, 18, J = 12 Hz), 4.32 (t,4), 4.10 (t,4), 7.80 (m, 4), 7.50 (m, 6). Anal. Calcd for C3JI3FeP2: C, 70.07; H, 7.00. Found C, 68.91; H, 6.95. Preparation of 1-(Diphenylphosphin0)-1'-(di-tert-butylphosphino)ferrocene,. 7. The ferrocenophane cleavage reaction (eq 2) was carried out essentially by the procedure of Seyferth and Withers" with minor modification. A solution containing the [llferrocenophane (10) (1.50 g, 5.14 mmol) in diethyl ether (-30 mL) at -78 "C was added dropwise to a stirred solution of phenyllithium (4 mL of a 1.95 M solution in benzene). The mixture was allowed to warm to room temperature slowly. The solution was then recooled to -78 OC, and excess di-tert-butylchlorophosphine (3 mL) in diethyl ether (3 mL) was added dropwise. The resulting mixture was slowly warmed to room temperature and was subsequently heated to a gentle reflux for 10 min. Precipitation of LiCl occurred. After being stirred for a further 20 min at room temperature, the solution was hydrolymd (HzO, 20 mL) and the ether layer separated and dried over anhydrous MgSO., for 90 min. The solvent volume was reduced to a few milliliters following filtration. The residual oil was chromatographed on neutral alumina to give a single orange band which eluted with diethyl ether/petroleum ether (10/90). Crystallization was initially attempted from petroleum ether, but this was unsuccessful; a mixture of acetone and methanol (20/80) was finally used, and a yellow crystalline solid was isolated. This compound was carefully washed with a few milliliters of cold petroleum ether and was vacuum dried at room temperature: yield 47%; 'H NMR (CDCl3) 6 1.12 (d, 18, J = 11.5 Hz), 4.30 (t, t), 4.37 (t, 2), 4.48 (t, 2), 4.62 (t, 2), 7.33 (m, 10). Anal. Calcd for

C30H3BFeP2: C, 70.06; H, 7.00. Found: C, 69.95; H, 6.95. Preparation of 1-(Dipheny1phosphino)-1'-(tert -butylphenylphosphino)ferrocene, 8, and 1-(Di-tert-butylphosphin0)-1'-(tert-butylphenylphosphino) ferrocene, 9. The title compounds were prepared from 11 by a procedure essentially identical with that used for the preparation of 7 (SchemeI). The alternative preparations of 8 and 9 using tert-butyllithium, 10, and di-tert-butylchlorophosphine or chlorodiphenylphosphine were also studied. The latter required hexane as a solvent, and the cleavage reaction was much slower. Complex Preparation. Pd(L-L)C12, Ni(L-L)X2,[Rh(LL)NBD][C104], and M(L-L)(CO), (L-L = Bis(tertiary phosphine);X = C1, Br; M = Mo, W).(i) [Pd(L-L)Cl,]. These complexes were prepared by the direct reaction of either Pd(PhCN)&12,Pd(COD)C12,or K2PdC14with a slight molar excess of the appropriate ligand in diethyl ether containing a few milliliters of methylene chloride or chloroform. The product complexes formed as red-orange precipitates in each case which were isolated by filtration. For crystallization the product (-300 mg) was dissolved in methylene chloride or chloroform (-5 mL), and a top layer of cyclohexane (-2.5 mL) was carefully added. Slow diffusion of the solvent layers resulted in the formation of crystalline samples. The crystals thus obtained were washed with n-hexane and vacuum dried. (ii) Ni(L-L)X2. These compounds were prepared by modest adaptations of published procedures and were isolated in all cases as green crystalline solids.12 (iii)[Rh(NBD)(L-L)][ClO,]. The procedure of Schrock and Osbornl8was used, and the compourds were isolated by two phase crystallization (CH2C12or CHC13with cyclohexane). (iv) M(CO),(L-L). These compounds were prepared by the literature procedure.12 X-ray Crystallographic Analyses of (L-L)PdC12CH2C12, (L-L)NiBrz,and (L-L)MO(CO)~.C~H, (L-L = 1). Crystallographic data for all three complexes are given in Table I. Crystals were mounted in nonspecific orientations on an Enraf-Nonius CAD4-F diffractometer. Final unit-cell parameters were obtained by least-squares on (2 sin @ / A values for 25 reflections (with 20 in the ranges 35-45O, 30-40, and 40-47', respectively, for the Pd, Ni, and Mo compounds) measured with Mo K a l radiation (A = 0.70930 A). The intensities of three check reflections were monitored every hour of X-ray exposure time throughout the data collections and in each case showed only small random fluctuations. The data were pr~cessed'~ and absorption corrections were made (Gaussian integration20*21), those reflections for which I 1 3a(I) were considered observed and employed in the solution and refinement of the structures. In the cases of the Mo and Ni complexes the space groups PI and Pn2,a were indicated by both the E statistics and the Patterson functions. Each of the structures was solved by conventional heavy-atom techniques; all non-hydrogen atoms not located from the Patterson function were positioned from subsequent Fourier syntheses. In the case of the Pd complex, all hydrogen atoms except those associated with the CH2C12solvent molecule were located on a difference map and were refined with isotropic thermal parameters; the solvent hydrogen positions were calculated (C-H = 0.98 A) and included as fixed atoms. For the Ni and Mo complexes all hydrogen atoms were placed in idealized positions [C(sp2)-H = 0.97; C(sp3)-H = 0.98 A] and included as fixed atoms in subsequent cycles of refinement. Neutral atom scattering factors from ref 22 were used for the non-hydrogen atoms and those of ref 23 for hydrogen atoms. Anomalous (18)Schrock, R. R.; Osborn, J. A. J. A m . Chem. Soc. 1976,98,2143. (19)The computer programs used include locally written programs for data processing and locally modified versions of the following: ORFLS, full-matrix least-squares, and ORFFE, function and errors, by W. R. Busing, K. 0. Martin, and H. A. Levy; FORDAP,Patterson and Fourier syntheses, by A. Zalkin; ORTEPII,illustration, by C. K. Johnson. (20) Coppens, P.; Leiserowitz, L.; Rabinovich, D. Acta Crystallogr. 1965,18,1035. (21)Busing, W. R.; Levy, H. A. Acta Crystallogr. 1967,22,457. (22)Cromer, D.T.;Mann, J. B. Acta Crystallogr., Sect. A 1968,A24, 321. (23)Stewart, R.F.; Davidson, E. R.; Simpson, W. T.J. Chem. Phys. 1966,42,3175. ~~

(17)Seyferth, D. M.;Withers, H. P. Organometallics 1982,1 , 1275.

Butler et al.

974 Organometallics, Vol. 4, No. 6, 1985 ClllI@

c1151

Figure 1. Stereoscopic views of the (L-L)PdC12,(L-L)NiBr2,and (L-L)Mo(CO), complexes (50% probability thermal ellipsoids are shown, and hydrogen atoms are omitted). scattering factors from ref 24 were employed for Pd, Ni, Mo, Br, C1, and P atoms. An isotropic type I extinction correction (Thornley-Nelmes definition of mosaic anisotropy with a Lorentzian distribution) was applied for the Ni comp0und,2”~’the (24) Cromer. D. T.: Liberman. D. J. Chem. Phvs. 1970.53. 1891. (25) Becker,’P. J.; Coppens,P: Acta Crystallog;., Sect. A 1974, A30, 129; 1974, A30, 148; 1975, A31, 417.

final value of g being 13.2 (2)X 104. The polarity of the Ni crystal was checked by parallel refinement, the R and R, ratios being 1.019 and 1.028,respectively. Maximum fluctuations on the final (26) Coppens, P.; Hamilton, W. C. Acta Crystallogr., Sect. A 1970, A26. 71. (27) Thornley, F. R.; Nelmes, R. J. Acta Crystallogr., Sect. A 1974, A30, 748.

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1,l'- Bis[(alkyl/aryl)phosphino]ferrocenes

Table I. Crystallographic Data'" (L-L)PdCl,*CH,Cl, (L-L)NiBr, C,H,,Cl,FeP,Pd.CH,Cl, C,H,,Br,FeNiP,

formula b

(L-L)Mo(CO),*C,H,

C,,H,,FeMoO,P,+C,H,

fw

816.63

772.91

840.49

cryst system

monoclinic

orthorhombic

triclinic

space group

P2,lc 9.8615 ( 8 ) 18.2322 ( 9 ) 19.1540 ( 1 5 ) 90 102.581 ( 4 ) 90 3361.1 ( 4 ) 4 1.614 1640 0.05 X 0.26 X 0.42 13.99 0.721-0.941 w -28 1.01-10.06 0.65 + 0.35 tan e zh,+ k , + 1 55 7675 4324 500 0.029 0.035 1.483 0.43 t0.8

Pn2,ac 20.4163 ( 1 5 ) 14.7573 (10) 10.2015 ( 6 ) 90 90 90 3073.6 ( 4 ) 4 1.670 1544 0.15 X 0.41 X 0.46 37.89 0.243-0.587 w -28 1.68-10.06 0.80 + 0.35 tan e + h,+ k, + 1 55 3680 1870 361 0.069 0.074 3.014 0.29 -1.7, + 1 . 3

Pid

a, A

b, A

c, a

a , deg P , deg Y , deg A3

v,

Z Dcalcd, g/cm3

F(000) cryst dimens, mm p(Mo Ka),cm-' transmissn factors scan type scan speed, deg/min scan range, deg in w data collected 2emax9 deg

unique reflctns reflectns with I no. of variables R

3o(I)

RW

goodness of fit

max A/u

residual density, e/A3

10.950 ( 2 ) 18.110 ( 3 ) 10.3433 (12) 101.777 ( 9 ) 93.322 (10) 83.059 ( 1 1 ) 1992.1 ( 5 ) 2 1.401 8 56 0.18 X 0.35 X 0.36 7.89 0.744-0.9 2 5 w -2e 1.44-10.06 0.65 t 0.35 tan e z h,z k, t 1 55 9096 6687 439 0.033 0.045 1.799 1.ae -0.8,t 0.7

'" Temperature 22 "C; Mo K a radiation ( h = 0.710 73 A ) ; graphite monochromator; takeoff angle 2.7'; aperture (2.0 + tan e ) X 4.0 mm at a distance of 173 mm from the crystal; scan range extended by 25% on both sides for background measurement; o z ( I )= S t 2B + [O.O4(S - B ) ] , (S = scan count, B = normalized background count); function minimized Z w( IF, I lFCl),where w = l / u z ( F ) , R = Z I I F ~ I l-F c l l /lFol, ~ and R, = ( ~ w ( l F -~ l F c t ) z / ~ w l F o l ~ ) l ' ~ Names: . dichloro[l,l'bis(dipheny1phosphino)ferrocene-P,P]palladium( 11); dibromo [ 1,l'-bis(dipheny1phosphino)ferrocene-P,P]nickel(11); tetracarbonyl[1,l'-bis(dipheny1phosphino)ferrocene-P,P]molybdenum(0 ) ; L-L = 1,l'-bis(diphenylphosphino)ferrocene, (C,H,PPh,),Fe. Nonstandard setting of Pna2,, equivalent positions: x , y, z ; 11, - x , */, t Y , I / , t z ; - x , 1 1 t~ y , -2; l l 2 t x, y , - z . Reduced cell. e Associated with the solvent molecule, parameter shifts associated with the complex did not exceed 0.090.

difference maps for all three structures were near heavy atoms. Atomic positional parameters are given in Table 11, selected bond lengths and angles in Table 111, and complete lists of molecular dimensions and structure factors are included in the supplementary material.

Discussion Crystal Structures. The three molecules studied by X-ray methods (Figure 1) contain 1,l'-bis(dipheny1phosphino)ferrocene, 1, coordinated via the two P atoms to PdC12,NiBr2, and MO(CO)~ moieties, thus completing cis square-planar, tetrahedral, and cis octahedral coordinations for Pd, Ni, and Mo atoms, respectively. The crystals of the P d complex contain dichloromethane solvate,11J6 crystals of the Ni complex are unsolvated, and the Mo crystals contain benzene solvate. The data for the Ni complex are somewhat less accurate, as a result of poorer crystal quality, than those for the Pd and Mo compounds. The P d coordination group is slightly distorted from exact planarity, with a fold about the C1(2).-P(2) axis; the C1 and P atoms are alternately above and below the ClzPz plane by 0.046-0.058 (1)A, with P d displaced by 0.0714 (3) A. Bond lengths and angles are as follows: Pd-P = 2.278 and 2.289 (1) 4mean 2.284 (6) 4 Pd-Cl = 2.340 and 2.358 (1) A, mean 2.349 (9) A, and P-Pd-P = 97.98 (4)' and C1-Pd-C1 = 89.96 (4)O (Table 111). These dimensions are close to those reported for the chloroform solvate: mean 2.292 and 2.348 A and 99.07 and 87.8O." The small, but statistizally significant, differences in the geometry about Pd in the two solvates probably arise

from packing effects and are not chemically important. In the chloroform solvate" the PdC1,P group is planar to within 0.01 A with the second P atom displaced 0.21 A from this plane in contrast to the arrangement described above. The pairs of Pd-C1 and Pd-P bond lengths in the chloroform solvate differ by 0.001 and 0.018 A compared with corresponding differences of 0.018 and 0.012 A in the dichloromethane solvate. The shorter mean Pd-P and (marginally) longer Pd-C1 distances in the present structure are consistent1' with the smaller P-Pd-P and larger C1-Pd-C1 angles. Molecules of the type BrzNi(PR3)zusually exhibit square-planar geometry a t Ni with small R groups, e.g., R = Me,2s but the steric influence of bulkier R groups results in tetrahedral geometry, e.g., R = Ph.29 In some examples both geometries are found, e.g., for the chelating ligand PhzPCHzPPhzboth square-planar and tetrahedral isomers are found in the same crystal.30 Consiglio and co-workers31have pointed out that most of the conventional chelating ligands used in catalysis afford diamagnetic nickel(I1) complexes. I t may be the bulk of the 1,l'-bis(dipheny1phosphino)ferroceneligand (1) in the present Ni complex which produces the tetrahedral coordination at Ni. The Ni-P bonds, mean 2.290 (9) 8, (Table 111), are (28) Mari, A,; Gleizes, A.; Dartiguenave, M.; Dartiguenave, Y. Inorg. Chim. Acta 1981,52, 83. (29) Jarvis, J. A. J.; Mais, R. H. B.; Owston, P. G.J. Chem. SOC.A 1968, 1473. (30)Kilbourn, B. T.;Powell, H. M. J. Chem. SOC.A 1970, 1688. (31)Morandini, F.;Consiglio, G.; Piccolo, 0.Znorg. Chim. Acta 1982, 52, 15.

976 Organometallics, Vol. 4, No. 6, 1985

Butler et al.

Table 11. Final Positional ( X lo4 for C and 0, X105for Heavy Atoms) and Isotropic Thermal Parameters (Ux lo3,A2) for (L-L)PdCl,.CH,Cl,, (L-L)NiBr,, and (L-L~Mo(CO);C,H, with Estimated Standard Deviations in Parentheses

Pd Fe Cl(1) Cl(2) Cl(3) Cl(4) P(1) P(2) C(1) C(2) C(3) C(4) C(5) C(6) C(7) C(8) C(9) C(10) C(11) C(12) C(13) C(14)

22751 49749 3887 26508 25219 40431 39840 18208 4862 6290 6516 5262 4243 3355 4564 5588 5040 3671 5451 5978 7113 7730

27778 (2) 30104 (3) 34341 (6) 22423 (6) 47238 (11) 44135 (12) 19891 (5) 33051 (5) 2072 (2) 2264 (2) 2293 (3) 2120 (2) 1979 (2) 3636 (2) 3875 (2) 4086 (2) 3987 (2) 3725 (2) 2006 (2) 2670 (3) 2694 (3) 2067 (3)

30560 (1) 50995 (3) 23929 (5) 19939 ( 5 ) 8692 (15) 23084 (15) 36040 (5) 40591 (5) 4534 (2) 4808 (2) 5565 (2) 5772 (2) 5141 (2) 4672 (2) 4424 (3) 5033 (3) 5645 (3) 5432 (2) 3163 (2) 2995 (3) 2691 (3) 2533 (3)

Ni

60391 63743 64212 49755 62343 67227 6213 6744 6500 5790 5648 6597 7077 6740

57748 83500 (33) 44337 (27) 60662 (33) 69462 (43) 61006 (46) 8028 (16) 8674 (16) 9451 (18) 9323 (19) 8443 (18) 7215 (16) 7919 (17) 8697 (19)

67900 (31) 54452 (33) 77713 (28) 60349 (32) 81950 (60) 50619 (58) 7361 (25) 7283 (22) 6631 (22) 6397 (30) 6801 (27) 4313 (24) 4153 (24) 3595 (29)

5950 (15) 5146 (16) 4998 (19) 5671 (24) 6482 (20) 6637 (18)

5415 (22) 5083 (28) 5432 (32) 5983 (32) 6354 (26) 5936 (30)

Fe Br(1) Br(2) P(1) P(2) C(1) C(2) C(3) C(4) C(5) C(6) C(7) C(8) C(23) C( 24) C(25) C(26) C( 27) C(28)

7598 (10) 7889 (12) 8553 (12) 8919 (13) 8606 (13) 7948 (14) 37356 (2) 26091 (3) 21011 (6) 40268 (6) 5575 (2) 3881 (3) 6186 (2) 1591 (2) 1573 (2) 1044 (2) 767 (3) 1121 (3) 1619 (3) 4000 (2) 3555 (3) 3696 (3) 4234 (3) 4423 (3) 659 (2) -445 (3) -1486 (3) -1449 (3) -361 (4) 684 (3) 2416 (3) 3595 (4)

27321 (1) 30336 (2) 21327 (4) 37700 (4) 3384 (2) 1422 (2) 1884 ( 2 ) 3538 (1) 2509 (2) 3279 (2) 3343 (2) 2639 (2) 2117 (2) 3503 (1) 3957 (2) 3504 (2) 2779 (2) 2765 (2) 2155 (2) 2551 (2) 2588 (2) 2226 (2) 1821 (2) 1793 (2) 1116 (2) 785 ( 2 )

52042 (2) 94286 (4) 62198 ( 7 ) 72269 ( 6 ) 3649 (3) 2714 (3) 6223 (3) 3627 (2) 7888 ( 3 ) 8382 (3) 9723 (3) 10084 (3) 8958 (3) 8813 (2) 10028 (3) 11002 (3) 10430 (3) 9071 (3) 5214 (3) 5689 ( 4 ) 4856 (5) 3572 (4) 3090 (4) 3905 (3) 6245 (3) 6356 ( 6 )

(L-L)PdCl,.CH,Cl, 28 C(15) 7203 (6) 34 C(16) 6064 (5) 48 C(17) 3325 (4) 44 C(18) 4033 (5) 3544 (6) 141 C(19) 2359 (6) 155 C(20) 1640 (6) 30 C(21) 2120 (5) 33 C(22) 722 (4) 33 C(23) 32 C(24) -678 (6) 48 C(25) -1471 (8) 45 C(26) -881 (10) 501 (9) 38 C(27) 1302 (6) 36 C(28) 929 (4) 43 C(29) 690 (5) 52 C(30) 103 (5) 51 C(31) 44 C(32) -307 (6) 37 C(33) -150 (6) 48 C(34) 476 (5) 58 C(35) 2837 ( 1 0 ) 64 (L-L)NiBr, 6058 (15) 37 C(9) 5975 (14) 42 C(10) 6990 (10) 56 C(11) 7490 (11) 66 C(12) 8097 (12) 31 C(13) 8207 (15) 33 C(14) 7662 (15) 43 C(15) 7105 (15) 39 C(16) 5613 (11) 54 C(17) 5279 (12) 77 C(18) 53 C(19) 4862 (19) 4751 (16) 40 C(20) 5102 (14) 43 C(21) 5495 (14) 60 C(22)

1406 (4) 1367 (3) 1050 (2) 532 (2) -178 (3) -378 (3) 132 (3) 838 (2) 4121 (2) 4079 (4) 4727 (5) 5375 (4) 5422 (3) 4794 (3) 2643 (2) 2741 (4) 2194 (5) 1561 (4) 1457 (4) 1998 (3) 4172 (4)

2677 (3) 2992 (3) 3568 (2) 4043 (2) 4034 (3) 3569 (3) 3110 (3) 3106 (2) 3942 (2) 3934 (3) 3838 (4) 3743 (3) 3755 (4) 3856 (3) 4501 (2) 5186 (3) 5513 (3) 5157 (4) 4481 (4) 4153 (3) 1552 (5)

72 57 34 51 63 58 59 47 45 70 96 95 86 65 38 67 78 78 52 128

8451 (23) 7573 (17) 6964 (14) 6341 (15) 6415 (21) 7055 (25) 7661 (19) 7603 (18) 7018 (20) 7811 (21) 7811 (39) 7076 (46) 6225 (31) 6232 (21)

3531 (26) 3994 (29) 9133 (22) 8885 (26) 9565 (31) 10459 (31) 10759 (27) 10086 (25) 9455 (26) 9790 (30) 10820 (45) 11547 (36) 11249 ( 2 8 ) 10213 (27)

65 53 30 42 60 68 59 52 50 57 108 102 777 61

80

(L-L)NiBr, 34 C(29) 54 C(30) 61 C(31) 62 C(32) 50 C(33) 57 C(34)

6579 (11) 6241 (12) 6170 ( 1 2 ) 6402 (14) 6715 (13) 6752 (16)

5339 (17) 4524 (18) 3863 (18) 4078 (20) 4870 (21) 5495 (18)

3703 (24) 3896 (24) 2900 (32) 1692 (28) 1442 (24) 2436 (26)

35 43 54 55 51 53

33 39 37 33 79 87 77 65 42 48 63 69 56 36 46 54 57 45 43 63 76 66 69 59 48 88

3855 (5) 2934 (5) 1729 (5) 1476 (4) 5572 (2) 5830 (3) 7002 (4) 7918 (3) 7692 (3) 6510 (2) 3048 (2) 1904 (3) 1152 (3) 1553 (4) 2681 (4) 3436 (3) 4890 (3) 3779 (3) 5273 ( 3 ) 2324 (3) 7576 (11) 8602 (12) 8347 (18) 8003 (15) 6890 (14) 6802 (12)

31 (3) -420 (2) -102 (2) 667 (2) 4077 (1) 4540 (2) 4751 (2) 4498 (2) 4042 (2) 3824 (2) 4680 (1) 4718 (2) 5396 (2) 6052 (2) 6021 (2) 5338 (2) 3168 (2) 1893 (2) 2175 (2) 3267 (2) 1556 (7) 1177 (8) 391 (13) -67 (9) 265 ( 1 0 ) 1057 (9)

6446 ( 7 ) 6344 (5) 6204 (5) 6170 (5) 7287 (3) 6453 (4) 6425 (4) 7234 (5) 8068 (4) 8085 (3) 7441 (3) 6800 (3) 6916 (4) 7690 (4) 8315 (4) 8216 (3) 4245 (3) 3655 (3) 5914 (3) 4244 (3) 9604 (12) 8621 (14) 8054 (21) 8858 (17) 9677 (15) 9994 (14)

117 93 99 78 39 61 72 77 71

51 40 49 66 71 68 54 49 52 48 42 214 (4) 244 (5) 357 (9) 271 (6) 262 (6) 254 (6)

Organometallics, Vol. 4,No.6, 1985 977

1,l'-Bis[(alkyl/aryl)phosphino]ferrocenes

0 157 ,PI

Table 111. Summary of Molecular Dimensions (A and deg) in (L-L)PdCl,, (L-L)NiBr,, and (L-L)Mo(CO), Pd-P Pd-Cl Ni-P Ni-Br Mo-P Mo-C

Pd, Ni, Mo 2.278, 2.289 (1) 2.340, 2.358 ( 1 ) 2.281, 2.299 ( 6 ) 2.344, 2.351 ( 4 ) 2.544, 2.576 (1) 1.969, 1.978 ( 3 ) 2.035, 2.041 ( 3 )

P-Pd-P C1-Pd-Cl P-Ni-P Br-Ni-Br P-Mo-P

Coordinations mean 2.284 ( 6 ) mean 2.349 ( 9 ) mean 2.290 ( 9 ) mean 2.348 ( 4 ) mean 2.560 ( 1 6 ) mean 1.974 ( 5 ) (trans to P) mean 2.038 ( 3 ) (cis to P)

97.98 ( 4 ) 89.96 ( 4 ) 102.5 ( 2 ) 127.0 ( 2 ) 95.28 ( 2 )

P...P

3.447 ( 1 )

P.9.P

3.573 ( 9 )

P.**P

3.783 (1)

Ferrocene Groupsa mean Fe-Co 1.636 ( 2 ) 1.666 7 ) Cp-Fe-Cp' 177.3 173.1 angle between 6.2 6.2 plane normals rotation from 39.5 -6.5 eclipsed conformation mean Fe-C( 1) 2.002 2.06 mean Fe-C( 2) 2.028 2.05 mean Fe-C( 3 ) 2.058 2.07 mean C( 1)-C( 2 ) 1.437 1.43 mean C( 2)-C( 3 ) 1.416 1.41 mean C( 3)-C( 4 ) 1.410 1.46 mean C-C-C at C( 1) 106.8 108 at C( 2,3) 108.3 108

1.646 1 ) 179.0 2.2 41.9 2.032 2.036 2.057 1.434 1.422 1.403 106.9 108.3

a Cp = centroid of cyclopentadienyl ring: 1 = 1 , 6 ; 2 = 2,5,7,10; 3 = 3,4,8,9.

marginally shorter than those in NiBr2(PPh3I2,2.334 (11) and Br-Ni-Br are very similar in the two molecules, mean 2.348 (4) A and 127.0 (2)' in the present compound vs. 2.338 (9) A and 126.3' in ref 29. The PNi-P angle in the present structure is significantly smaller than in NiBr2(PPhJ2, 102.5 (2) vs. 110.4 (2)') presumably as a result of the steric constraints of the chelating ferrocene ligand. In the Mo coordination sphere the Mo-P bond lengths, mean 2.560 (16) A, are a t the upper end of the range usually found. The Mo-C bond lengths are normal for those involving carbonyl ligands but show a pronounced trans effect of the phosphine ligands, mean Mo-C being 1.974 (5) A for bonds trans to P and 2.038 (3) A for bonds cis to P. The ferrocene ligands in the three molecules have roughly similar geometries, with each iron atom sandwiched between two cyclopentadienyl rings and both phosphino groups on one side of the ligand (Figure 1). The cyclopentadienyl rings are planar within experimental error (maximum displacement 2 . 4 5 ~but ) deviate slightly from being parallel, the angles between the plane normals being 6.2, 6.2, and 2.2' in the Pd, Ni, and Mo compounds, respectively. In the P d and Mo compounds the noncoplanarity is such that the spacing between the rings decreases toward the phosphine Substituents; in addition the P atoms are slightly displaced from the planes toward the Fe atom, by 0.062 (1) and 0.035 (1) A in the P d compound and by 0.017 (1) and 0.026 (1) 8, in the Mo compound (Figure 2). In the Ni compound, in contrast, the spacing between the rings increases toward the phosphine substituents: one P is displaced from ita ring plane by 0.157(6)A away from the Fe atom and the other P by 0.087 (6) A toward Fe. The two cyclopentadienyl rings are approximately staggered in the Pd and Mo compounds (rotations of 14.6 and 12.1°,respectively, from exact staggered conformations (Table 111)); in contrast, the conformation in the Ni com-

A,29and Ni-Br

I

,

4

Pd

, .-..-

62 \ i \i

'P2

o

0017

...

o

h

.,r

\

378

22

p2e .-. 0%20

0 oar

Staggered

Eclipsed

Staggered

(395)

(65 )

(41 91

Figure 2. Schematic representations of deviations from planarity (if)and of ring orientations (deg) in the Pd, Ni, and Mo complexes.

pound is nearly eclipsed (6.6' from an exactly eclipsed position). These differences in ring tilt, P displacement, and conformation (Figure 2) are probably related to the steric requirements sf bonding to the Pd, Ni, and Mo atoms, the P.-P distances being 3.45, 3.57, and 3.78 A, respectively. The configurations at the metal centers are distorted from normal geometry, with P-M-P angles of 97.98 (4) and 95.28 (2)' for M = P d and Mo, increased from the ideal values of 90"; in the Ni complex the angle is decreased from the ideal 109.5"tetrahedral value to 102.5 (2)'. The exact geometries adopted are presumably compromises between the various bonding and steric forces. Similar variations in geometry have been found in a series of related Rh ~ o m p l e x e s . ~ The C-C bond lengths and C-C-C angles in the cyclopentadienyl rings show substituent-induced variations. For the more accurately determined Pd and Mo structures, the mean C-C distances involving the substituted C(1) and C(6) atoms are the longest in the rings at 1.437 and 1.434 A,respectively; adjacent C-C bonds are 1.416 and 1.422 A,with the final C(3)-C(4) and C(8)-C(9) lengths being 1.410 and 1.403 A. C-C-C angles at substituted atoms average 106.8 and 106.9', slightly reduced from the ideal 108', with the other angles averaging 108.3'. Fe-C distances are shortest for the substituted C(1) and C(6) atoms, mean 2.002 and 2.032 A for the Pd and Mo compounds, respectively; F e C ( 2 ) types average 2.028 and 2.036 A and Fe-C(3) types 2.058 and 2.057 A, respectively. All these bond and angle variations are very similar to those observed in phosphine-bridged f e r r o ~ e n o p h a n e s . Similar ~~ variations within the cyclopentadienyl rings are observed in a tris(di-tert-butylphosphino) [ (dimethy1amino)ethyllf e r r ~ c e n ewhere ,~ C-C bonds and angles average 1.426 A and 106.5' at substituted C atoms and 1.416 A and 109.0' at unsubstituted C atoms; however, in that compound the Fe-C bonds are longer at substituted C atoms, mean 2.092 A vs. 2.044 A for unsubstituted atoms, with substituent P and C atoms displaced away from the Fe atoms as a result of steric interactions. The results for the Ni compounds are less accurate, and bond length and angle variations cannot be considered significant. P-C bond lengths are in the ranges 1.804-1.828 (4), 1.81-1.84 (2), and 1.805-1.842 (3) A, in the Pd, Ni, and Mo compounds, respectively; those bonds involving the cyclopentadienyl C atoms seem to be slightly shorter in the Pd and Mo compounds, means 1.807 and 1.814 A vs. 1.822 and 1.838A for P-C(pheny1) bonds (differences for the Ni compound are again not statistically significant). Angles at P are 101.3-123.1 (l),102-119 (l),and 101.0-122.0 (1)' in the Pd, Ni, and Mo compounds, respectively. Bond lengths and angles in the phenyl rings are within the ranges (32)Butler, I. R.;,CuUen,W. R.;Einstein, F. W. B.; Rettig, S. J.; Willis, A. J. Organometallics 1983, 2, 128. (33) Rosenblum, M.; Banerjee, A. K.; Danieli, N.; Fish, R. W.; Schlatter, V. J. Am. Chem. SOC.1963, 85, 316.

978 Organometallics, Vol. 4, No. 6, 1985

Table IV. Analytical and Spectroscopic Data for Complexes anal. found (calcd) L-L C H 'HNMR,' 6 3 47.31 (47.91) 6.88 ( 7 . 0 0 ) 1.68 (d, 36, J = 1 2 Hz), 4.49 (bs, 4), 4.85 (bs, 4 ) 6 51.98 ( 5 2 . 0 8 ) 1.53 (d, 18, J = 16 Hz), 4.0-4.4 (m, 8), 7.68 (m, 4.96 ( 5 . 2 1 ) 6), 8.45 (m, 4 ) 7 45.80 ( 4 5 . 9 0 ) 4.60 4.59) 1.63 (d, 18, J = 9 Hz), 3.85-4.40 (hm, 4 ) , 7.327.52 (m, 6 ) , 7.88-8.23 (m, 4 ) 8c 1.40 (d, 9, J = 16 Hz), 3.80 (m, 2), 4.25 (m, l), 4.40 (m, 2 ) , 4 . 6 5 (m, 2), 4.80 (m, l ) ,7.258.60 (m, 1 5 )

x c1

Pd( L-L)X,

c1

c1 c1 Ni( L-L)X,

Brd Cld Brd

[Rh( L-L)NBD]C10,

' CDCl,.

Butler et al

CHCl, solvate.

1 3 3 6

52.76 (52.82) 51.25 (51.69) 45.53 (45.06) 54.24 ( 5 4 . 9 5 )

3.72 6.95 6.53 5.28

7

53.'70 ( 5 4 . 9 3 )

5.25 ( 5 . 4 4 )

8

56.49 ( 5 6 . 2 0 )

4.86 ( 4 . 9 8 )

CD,Cl,.

3.62) 7.29) 6.35) 5.44)

1.10 (d, 18,J = 14 Hz), 1.80 (bm, 2), 4.00 (bm, 2), 4.00-4.30 (bm, 8), 5.25 (bm, 2), 5.68 (bm, 2), 7.78 (m, 6 ) , 8.78 (m, 4 ) 1 . 5 0 (d, 18, J = 12 Hz), 1.70 (bm, 2), 3.90 (bm, 2), 4 . 6 2 (bm, 2), 4.48 (bm, 2), 4.35 (bm, 21, 4.20 (bm, 2), 5.70 (bm, 4), 7.65 (m, 6), 7.85 (m, 4) 1.30 (d, 9 ) , J = 10 Hz), 1.60 (bd, 2 ) , 1.82 (bd, 2), 3.88 (4,l ) ,4.00-4.60 (m, 9 includes sharp resonances at 4.02, 4.07, 4.20, 4.32, 4.39, 4.45, 4.57), 5.43 (bs, l), 5.50 (bs, l ) , 7.24 (m, 2), 7.48 (m, 3), 7.70 (m, 6), 8.32 (m, 2 ) 8.62 (m, 2 )

Paramagnetic. Scheme I ( I

) PhLi

(11)

CIPPh(CMe31

-PPh2 FP

( I

I

I l l

Me3CLi CIPPh2

*PPh(CMes)

I

8

9

usually found, with slightly shorter outer bond lengths, even after libration corrections. Intermolecular distances correspond to normal van der Waals interactions. The solvent molecules, dichloromethane (in the P d complex) and benzene (in the Mo complex), exhibit fairly large thermal motion, with rootmean-square displacements of up to 0.4 and 0.6 A, respectively. N M R Studies. The metal complexes of the 1,l'ferrocenylbis(tertiary phosphines) can be regarded as [3]ferrocenophanesand as such have a formal analogy with cyclohexane, 4 and 5 being equivalent to the chair and half-chair forms. Apart from this work in which one of the three derivatives has been found to have the eclipsed confirmation, two others with this structural feature have been established by X-ray crystallography, namely, F ~ ( T ~ - C ~ and H~)~

Fe(.r15-C5H4)2S2Se.34v35 Variable-temperature NMR studies have indicated that the eclipsed conformation exists in solution for most [3]ferrocenophanes with group 4 and 6 atoms in the (34) Bernal, I.; Davis, B. R. J. Cryst. Mol. Struct. 1972,2, 107. (35) Osbome,A. G.; Hollands, R. E.; Howard, J. A. K.; Bryan, R. F. J. Organornet. Chem. 1981,205, 395.

bridge,36,37one exception being the compound with an S2CPh2bridge when the rings appear to be staggered as in 5. The barrier to chair-to-chair reversal analogous to 4a + 4b can be high as in the S3bridge (AG* = 80.1 kJ mol-') resulting in a limiting ABCD NMR spectrum for the v5C5H4groups at ambient temperatures. In other cases, e.g., with (-CH2),S (AG* = 34.6 kJ m01-l)~'~ or (-S)2GeMe237a bridges the molecules are fluxional a t ambient temperatures and limiting NMR spectra are obtained only on strong cooling (ca. -100 "C). The 'H NMR spectra of the compounds M(L-L)(CO), (L-L = 1; M = Cr, Mo) at 400 MHz exhibit the typical pair of multiplets, in the s5-C5H4region, of a fluxional [3]ferrocenophane, the main distinction between the two compounds being a slightly greater chemical shift differSence ~ between the triplets for the Cr compound. Since the molybdenum compound has a staggered conformation in the solid state, it is probable that in solution both molecules are fluxional in the sense 5a + 5b. On cooling the (36) Bishop, J. J.; Davison, A. Inorg. Chem. 1971, 10, 826. (37) (a) Davison, A,; Smart, J. C. J. Organomet. Chem. 1979,174,321. (b) Abel, E. W.; Booth, M.; Orrell,K. G. J.Organomet. Chem. 1981,208, 213. ( c ) Abel, E. W.; Booth, M.; Brown, C. A.; Orrell, K. G.;Woodford, R. L. J . Organomet. Chem. 1981, 214, 93.

Organometallics, Vol. 4,No. 6, 1985 979

1,l'-Bis[(alkyllaryl)phosphino]ferrocenes solutions to -85 "C only a slight broadening is seen in the 'H NMR spectrum. The (L-L)M(CO), complexes of 1,l'-bis(dimethy1arsino)ferrocene are also fluxional in solution, probably in the same manner, although Davison and c o - ~ o r k e r speculated s~~ that the equilibrium would be of the type 4a 4b. The barriers to ring reversal are low as would be expected from the bulk of the ring substituent~.~~%~ Ligand Preparation. The symmetrically substituted ligands 1 and 3 have been prepared previously from the appropriate chlorophosphine and the dilithioferrocene/ T M E D adduct ( T M E D = tetramethylethylenediamine).4rsJ2The same procedure has now been applied to the synthesis of 6 as meso and racemic isomers as shown in eq 1. ,lLFe

TMED t 2CIP(CMe3)Ph

-

-PPh(CMe3) (1 1

Fe -PPh(CMes)

-Ll'

The unsymmetrically substituted ligands 7-9 were -PR'R'

Fe -PR3R4 6.R':R3=Ph:R2=R4=CMe3 7 . R'=R2=Ph:R3=R4=CMe3 8 . R' = Ph: R 2 = R 3 = R 4 =CMe3 9 , R ' = CMe3: R 2 = R 3 = R4=Ph

synthesised as shown in Scheme I. A route to 7 is outlined in more detail in eq 2. The first step utilizes the bridge PPh

Fe

e

PhLl

e

P FP

P

h

2 CIP(CMeal2

10

7

cleavage reaction of the [l]ferrocenophane (10) discovered by Seyferth and Withers.I7 This is an extremely effective method of activating the second ring for further substitution. In our hands the bridge cleavage reactions are best carried out a low temperature (-78 to -10 "C) in either diethyl ether or n-hexane solution.38 All routes shown in Scheme I give the anticipated products, however, the most convenient syntheses of the compounds 7-9 were found to be from 10. This is largely because the starting compound can be prepared relatively easily from commercially available materials and because the bridge cleavage reaction of 10 gives cleaner product mixtures compared with similar cleavage reactions of 11. The preferred lithium reagent to effect bridge cleavage is phenyllithium rather than tert-butyllithium since the latter reagent often affords tert-butylphosphine containing byprodu& which are difficult to separate from the desired product by chromatography. Some byproducts actually isolated include the knowdB (dipheny1phosphino)ferrocene (12a) isolated during the synthesis of 7 from 10 and (tert-butylpheny1phosphino)ferrocene (12b) isolated during the synthesis of 8 from 1 (38) n-Hexane waa used aa solvent in reactions involving MesCLi since Seyferth and Withers report" a reaction with diethyl ether under these conditions. (39) Sollott, G. P.; Mertway, H. H.; Portnoy, S.; Snead, J. L. J. Org. Chem. 1963,28,1040.

PR'R Fe

a 120. R ' . R ~ = Ph b. R'= Ph: R2=CMe3

Fe

Fe

( M e 3 C ) 2 P e

-PPh2 13

Another byprodud obtained during the synthesis of 7 from 10 is probably the tris(tertiary phosphine) 1341which could be formed following an alternative bridge cleavage reaction of 10 by the initial lithium derivative shown in eq 2. Similar bridge cleavage reactions by the lithiated products have been de~cribed.,~ The analytical and spectroscopic data for 6-8 are in accord with the proposed structures. Compounds 8 and 9 were found to be difficult to obtain pure even after repeated chromatography, however, the NMR spectrum and mass spectra43are in accord with the expected structures. The racemic isomer of 6 showed only one PCMe3resonance in both lH and 31PNMR the 31Presonance a t 7.77 ppm being almost halfway between that of 1 (-17.61 ppm) and 3 (26.48 ppm). 'H NMR spectra of compounds containing P(Ph)(CMe3)groups, 6,8, and 9, show broadened phenyl resonances split into a 2:3 multiplet. In contrast a broad singlet is observed for the PPh2 groups in 1, 7, and 8. Metal Complexes. The reaction of ligands 1, 3, 6, 7, and 8 with either Pd(PhCN)C12,K2PdC14,or Pd(COD)C12 gives the Pd(L-L)C12compounds (L-L = 1,3, rac-6,7, and 8) in essentially quantitative yield based on palladium. The analytical data and spectroscopic properties4 support of the formulation, and all should have structures analogous to that of the derivative of 1 described above (Figure 1). Ligand coordination results in significant 'H chemical shifts in the resonances of the ferrocenyl protons. This is particularly evident in the data for 7 where there is a considerable downfield shift associated with the 2,5,2',5' protons on the cyclopentadienyl rings resulting in an unusually broad range of ring proton resonances (>1ppm). The new rhodium(1) species [Rh(L-L)NBD]ClO, have been prepared for the ligands rac-6, 7, and 8. The analogous complexes of 1and 3 have been described previously, and crystal structures of the derivatives of 1, 3, 6, and 7 have been determined.4~~ Basically all have a more or less distorted cation with "square-planar" coordination around the Rh atom. The NMR spectra are in accord with this f~rmulation.,~The complex of ruc-6 shows a doublet at (40) Compound 12b was previously isolated as the sulfide by Seyferth and Withers.17 12b: 'H NMR (CDClJ S 1.05 (d, 9, JP-H= 12 Hz), 3.90 (s, 5), 4.00 (bs, 2), 4.45 (bs, 2), 7.25-7.80 (m, 5); MS, m / e 350 (M+). This = compound readily oxidizes. Oxide of 12b: 'H NMR S 1.10 (d, 9, JP-H 12 Hz), 4.00 (s,5), 4.43 (m, 3), 4.82 (m, l),7.50-7.70 (m, 3), 7.90-8.20 (m, 2); MS, m / e 366 (M+). (41) 13: MS m / e 806 (M+). Similar compounds have been isolated as byproduda from the reactions of 10 with ClPPhz or C1P-i-Pr, as in eq 2. (42) (a) Butler, I. R.; Cullen, W. R. Can. J. Chem. 1983,61,147. (b) Withers, H. P.; Seyferth, D.; Fellmann, J. D.; Garrow, P. E. Organometallics 1982,1, 1283. (43) 8: 'H NMR (CDC13) 6 1.00 (d, 9, JP-H = 12 Hz), 3.71 (m, l), 392-4.50 (m, 7), 7.23-7.50 (m, 13), 7.50-7.80 (m, 2); MS, m / e 534 (M'). A trace of phosphine oxide